Video processing system

ABSTRACT

A video processing system includes: an object movement information acquiring means for detecting a moving object moving in a plurality of segment regions from video data obtained by shooting a monitoring target area, and acquiring movement segment region information as object movement information, the movement segment region information representing segment regions where the detected moving object has moved; an object movement information and video data storing means for storing the object movement information in association with the video data corresponding to the object movement information; a retrieval condition inputting means for inputting a sequence of the segment regions as a retrieval condition; and a video data retrieving means for retrieving the object movement information in accordance with the retrieval condition and outputting video data stored in association with the retrieved object movement information, the object movement information being stored by the object movement information and video data storing means.

This application is a National Stage Entry of PCT/JP2015/000531 filed onFeb. 5, 2015, which claims priority from Japanese Patent Application JP2014-026467 filed on Feb. 14, 2014, the contents of all of which areincorporated herein by reference, in their entirety.

TECHNICAL FIELD

The present invention relates to a video processing system, a videoprocessing device, a video processing method, and a program.

BACKGROUND ART

A monitoring system which uses a monitoring camera and monitors a givenmonitoring target area is known. Such a monitoring system is configuredto make it possible to store video images captured by the monitoringcamera into a storage device and retrieve and reproduce a desired videoimage when necessary. However, it is extremely inefficient to reproduceall of the video images and manually find a desired video image.

Therefore, there is a known technique which enables retrieval of a videoimage in which an object performing specific behavior is recorded bydetecting and storing metadata of objects moving in the captured videoimages. Use of such a technique enables retrieval of a video image inwhich an object performing specific behavior is recorded from among alarge number of video images captured by the monitoring camera.

As such a technique for retrieving a video image in which an objectperforming specific behavior is recorded from among a large number ofvideo images, for example, Non-Patent Document 1 is known. Non-PatentDocument 1 discloses a technique of extracting the shape feature andmotion feature of an object and the shape feature of a background andcompiling them into a database in advance, and creating a query with ahand-drawing sketch of three elements composed of the shape of a movingobject, the motion of the moving object and a background and performingretrieval of a video image. In Non-Patent Document 1, a database isprepared by calculating the average vector of optical flows (OFs) inregions of a moving object in each of frame images and regardingcontinuous data obtained by gathering the vectors in the respectiveframe images as the motion feature of the moving object. Likewise,continuous data of vectors is extracted from a hand-drawing sketch drawnby the user and regarded as the motion feature of a query.

-   Non-Patent Document 1: Akihiro Sekura and Masashi Toda, “The Video    Retrieval System Using Hand-Drawing Sketch Depicted by Moving Object    and Background,” Information Processing Society of Japan,    Interaction 2011

There is a case where a monitoring system using a monitoring cameraneeds to separate a monitoring target area into a plurality of regionsdetermined in advance and, without considering a movement path in theregions, retrieve a video image of a person or the like moving from onespecific region to another specific region. For performing suchretrieval by using the technique disclosed in Non-Patent Document 1,there is a need to input a number of queries in which movement paths inthe regions are different. This is because according to the techniquedisclosed in Non-Patent Document 1, a video image of a person or thelike moving in the same regions but moving through a movement path inthe regions different from a movement path of a query may be excludedfrom a retrieval subject.

However, in a case where there are a variety of movement paths in theregions, the number of movement paths for moving in the regions is huge,and it is actually difficult to input a number of queries includingdifferent movement paths in the regions. Therefore, complete retrievalis difficult.

SUMMARY

Accordingly, an object of the present invention is to provide a videoprocessing system which solves the abovementioned problem, namely, aproblem that it is difficult to completely retrieve video images of aperson or the like moving from a specific region to another specificregion without considering movement paths in the regions.

In order to achieve the object, a video processing system as an aspectof the present invention includes:

an object movement information acquiring means for detecting a movingobject from video data and acquiring movement segment region informationand segment region sequence information as object movement information,the video data being obtained by separating a monitoring target areainto a predetermined plurality of segment regions and shooting themonitoring target area, the moving object moving in the plurality ofsegment regions, the movement segment region information representingsegment regions where the detected moving object has moved, the segmentregion sequence information representing a sequence of the segmentregions corresponding to movement of the moving object;

an object movement information and video data storing means for storingthe object movement information in association with the video datacorresponding to the object movement information, the object movementinformation being acquired by the object movement information acquiringmeans;

a retrieval condition inputting means for inputting the segment regionsand a sequence of the segment regions as a retrieval condition, thesegment regions showing movement of a retrieval target object to beretrieved; and

a video data retrieving means for retrieving the object movementinformation in accordance with the retrieval condition and outputtingvideo data stored in association with the retrieved object movementinformation, the object movement information being stored by the objectmovement information and video data storing means, the retrievalcondition being inputted by the retrieval condition inputting means.

Further, a video processing device as another aspect of the presentinvention includes:

an object movement information acquisition part configured to detect amoving object from video data and acquire movement segment regioninformation and segment region sequence information as object movementinformation, the video data being obtained by separating a monitoringtarget area into a predetermined plurality of segment regions andshooting the monitoring target area, the moving object moving in theplurality of segment regions, the movement segment region informationrepresenting segment regions where the detected moving object has moved,the segment region sequence information representing a sequence of thesegment regions corresponding to movement of the moving object;

an object movement information and video data storage part configured tostore the object movement information in association with the video datacorresponding to the object movement information, the object movementinformation being acquired by the object movement informationacquisition part;

a retrieval condition input part configured to input the segment regionsand a sequence of the segment regions as a retrieval condition, thesegment regions showing movement of a retrieval target object to beretrieved; and

a video data retrieval part configured to retrieve the object movementinformation in accordance with the retrieval condition and output videodata stored in association with the retrieved object movementinformation, the object movement information being stored by the objectmovement information and video data storage part, the retrievalcondition being inputted by the retrieval condition input part.

Further, a video processing method as another aspect of the presentinvention includes:

detecting a moving object from video data, acquiring movement segmentregion information and segment region sequence information as objectmovement information, and storing the object movement information inassociation with the video data corresponding to the object movementinformation, the video data being obtained by separating a monitoringtarget area into a predetermined plurality of segment regions andshooting the monitoring target area, the moving object moving in theplurality of segment regions, the movement segment region informationrepresenting segment regions where the detected moving object has moved,the segment region sequence information representing a sequence of thesegment regions corresponding to movement of the moving object; and

inputting the segment regions and a sequence of the segment regions as aretrieval condition, retrieving the object movement information inaccordance with the inputted retrieval condition, and outputting videodata stored in association with the retrieved object movementinformation, the retrieval condition being inputted by the retrievalcondition input part, the segment regions showing movement of aretrieval target object to be retrieved.

Further, a computer program as another aspect of the present inventionincludes instructions for causing a video processing device to functionas:

an object movement information acquisition part configured to detect amoving object from video data and acquire movement segment regioninformation and segment region sequence information as object movementinformation, the video data being obtained by separating a monitoringtarget area into a predetermined plurality of segment regions andshooting the monitoring target area, the moving object moving in theplurality of segment regions, the movement segment region informationrepresenting segment regions where the detected moving object has moved,the segment region sequence information representing a sequence of thesegment regions corresponding to movement of the moving object;

an object movement information and video data storage part configured tostore the object movement information in association with the video datacorresponding to the object movement information, the object movementinformation being acquired by the object movement informationacquisition part;

a retrieval condition input part configured to input the segment regionsand a sequence of the segment regions as a retrieval condition, thesegment regions showing movement of a retrieval target object to beretrieved; and

a video data retrieval part configured to retrieve the object movementinformation in accordance with the retrieval condition and output videodata stored in association with the retrieved object movementinformation, the object movement information being stored by the objectmovement information and video data storage part, the retrievalcondition being inputted by the retrieval condition input part.

With the abovementioned configurations, the present invention enablescomplete retrieval of video images of a person or the like moving from aspecific region to another specific region without considering movementpaths in the regions.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a view for describing the overview of a video processingdevice according to a first exemplary embodiment of the presentinvention;

FIG. 2 is a block diagram of the video processing device according tothe first exemplary embodiment of the present invention;

FIG. 3 is a flowchart showing an example of an operation performed whenthe video processing device according to the first exemplary embodimentof the present invention stores object movement information;

FIG. 4 is a flowchart showing an example of an operation performed whenthe video processing device according to the first exemplary embodimentof the present invention outputs video data;

FIG. 5 is a view for describing an operation of the video processingdevice according to the first exemplary embodiment of the presentinvention;

FIG. 6 is a view for describing the overview of a video processingdevice according to a second exemplary embodiment of the presentinvention;

FIG. 7 is a view for describing the overview of the video processingdevice according to the second exemplary embodiment of the presentinvention;

FIG. 8 is a block diagram of the video processing device according tothe second exemplary embodiment of the present invention;

FIG. 9 is a block diagram for describing the configuration of atrajectory information acquisition part shown in FIG. 8;

FIG. 10 is a view for describing the state of a trajectory determined bya trajectory information and segment region associating part;

FIG. 11 is a view for describing the state of a trajectory determined bythe trajectory information and segment region associating part;

FIG. 12 is a view for describing the state of a trajectory determined bythe trajectory information and segment region associating part;

FIG. 13 is a view showing an example of trajectory state informationinputted into a query input part;

FIG. 14 is a view showing an example of trajectory state informationinputted into the query input part;

FIG. 15 is a view showing an example of trajectory state informationinputted into the query input part;

FIG. 16 is a view showing an example of feedback of a gesture recognizedby a gesture recognition part;

FIG. 17 is a flowchart showing an example of an operation performed whenthe video processing device according to the second exemplary embodimentof the present invention stores object movement information;

FIG. 18 is a flowchart showing an example of an operation performed whenthe video processing device according to the second exemplary embodimentof the present invention outputs video data;

FIG. 19 is a view for describing segment regions separated by a videoprocessing device according to a third exemplary embodiment of thepresent invention;

FIG. 20 is a view for describing change of segment regions in accordancewith an enlarging/shrinking operation;

FIG. 21 is a schematic block diagram for describing the overview of theconfiguration of a video processing system according to a fourthexemplary embodiment of the present invention; and

FIG. 22 is a schematic block diagram for describing the overview of theconfiguration of a video processing device according to a fifthexemplary embodiment of the present invention.

EXEMPLARY EMBODIMENTS

Next, the exemplary embodiments of the present invention will bedescribed in detail referring to the attached drawings.

First Exemplary Embodiment

Referring to FIG. 1, a video processing device 1 according to a firstexemplary embodiment of the present invention is a device which storesvideo images captured by an external device such as a monitoring camera,retrieves a desired video image from among the stored video images, andoutputs the video image to an output device such as a monitor.

Referring to FIG. 2, the video processing device 1 according to thefirst exemplary embodiment of the present invention has an objectmovement information acquisition part 11 (an object movement informationacquiring means), a video data and metadata DB (DataBase) 12 (an objectmovement information and video data storing means), a retrievalcondition input part 13 (a retrieval condition inputting means), and ametadata check part 14 (a video data retrieving means). Herein, thevideo processing device 1 is an information processing device includingan arithmetic device and a storage device. The video processing device 1realizes the respective functions described above by execution of aprogram stored in the storage device by the arithmetic device.

The object movement information acquisition part 11 has a function ofacquiring object movement information including movement segment regioninformation and segment region sequence information from video datareceived from an external device such as a monitoring camera (a videodata acquiring means). To be specific, the object movement informationacquisition part 11 receives video data from an external device such asa monitoring camera. Subsequently, the object movement informationacquisition part 11 separates a monitoring target area in an image ofthe received video data into a plurality of segment regions determinedin advance, and detects a person (a moving object) moving in the segmentregions.

Herein, segment regions are a plurality of regions obtained byseparating a monitoring target area, and are regions indicating units ineach of which behaviors of a person are gathered. The object movementinformation acquisition part 11 separates a monitoring target area basedon, for example, the definition of segment regions stored in a segmentregion range storage part, which is not shown in the drawings.

The range of a segment region may be any range. For example, it ispossible to define the range of a segment region on the basis ofspecific spaces such as a room and a corridor, or define the range of asegment region based on the behavior of a person (e.g., the frequency ofpassage of a person) or the like. The range of a segment region may beproperly changed based on the frequency of passage of a person, thebehavioral tendency of a person, or the like. As described later, theuser can retrieve metadata (object movement information) for eachsegment region. Therefore, it becomes possible to define rooms andcorridors as segment regions and thereby retrieve video data for eachroom and each corridor.

Further, detection of a moving person by the object movement informationacquisition part 11 is possible by using a variety of known techniques.The object movement information acquisition part 11 can detect a movingperson by obtaining a difference between an image frame of video dataand a background image acquired in advance. Also, the object movementinformation acquisition part 11 can check whether or not the samepattern as an image region called a template appears in an image frameand thereby detect a person having the same pattern as the template, forexample. Alternatively, the object movement information acquisition part11 may detect a moving object by using a motion vector. Moreover, theobject movement information acquisition part 11 can track a movingobject by using a Kalman filter or a particle filter. Thus, in detectionof a moving person by the object movement information acquisition part11, it is possible to use various methods by which it is possible todetect a person moving in a plurality of segment regions.

The object movement information acquisition part 11 thus detects amoving person. Then, the object movement information acquisition part 11acquires movement segment region information indicating segment regionswhere the detected person moves and segment region sequence informationindicating the sequence of the segment regions corresponding to themovement of the detected person, as object movement information(metadata).

Herein, movement segment region information is information indicatingsegment regions where the detected person moves. As described above, theobject movement information acquisition part 11 separates a monitoringtarget area into a plurality of segment regions determined in advance.Therefore, the object movement information acquisition part 11 detectssegment regions where the detected person moves, and acquires thedetected segment regions as movement segment region information.Acquisition of movement segment region information by the objectmovement information acquisition part 11 can be realized by using avariety of methods, for example, describing the trajectory of movementof a person and associating the trajectory with segment regions, orsequentially acquiring segment regions where a person appearing in therespective image frames exists.

Segment region sequence information is information indicating thesequence of segment regions corresponding to movement of the detectedperson. In other words, segment region sequence information isinformation indicating the sequence of passage in segment regions wherethe detected person passes. Acquisition of segment region sequenceinformation by the object movement information acquisition part 11 canalso be realized by using a variety of methods, for example, associatingthe trajectory of movement of a person with segment regions, ordetermining the sequence of passage in segment regions by using shootingtime of each image frame.

Thus, the object movement information acquisition part 11 acquiresinformation indicating segment regions where a person moves, as movementsegment region information. Moreover, the object movement informationacquisition part 11 acquires, in addition to the movement segment regioninformation, the passage sequence at a time when the person moves in thesegment regions indicated by the movement segment region information, assegment region sequence information. Consequently, the object movementinformation acquisition part 11 can acquire object movement informationcomposed of movement segment region information indicating segmentregions through which a person moving in a plurality of segment regionspasses and segment region sequence information indicating the passagesequence of the segment regions. After that the object movementinformation acquisition part 11 transmits the acquired object movementinformation to the video data and metadata DB 12.

The object movement information acquisition part 11 may be configuredto, when acquiring object movement information, acquire time informationindicating time when a detected person passes through a segment region(time when the person appears in the segment region and time when theperson exits the segment region), and place information indicating theplace of the segment region. In a case where the object movementinformation acquisition part 11 acquires time information and placeinformation, the acquired time information and place information aretransmitted to the video data and metadata DB 12 together with theobject movement information (or included in the object movementinformation). Place information may be included in movement segmentregion information.

Further, the object movement information acquisition part 11 composesobject movement information so as to be capable of retrieving video datacorresponding to object movement information based on the objectmovement information (so as to be capable of associating object movementinformation with video data corresponding to the object movementinformation). For example, the object movement information acquisitionpart 11 provides object movement information with information foridentifying video data from which the object movement information isacquired. Moreover, for example, the object movement informationacquisition part 11 provides object movement information with movementstart time and movement end time of a detected person. By providingobject movement information with such information, it becomes possibleto associate and store object movement information and video datacorresponding to the object movement information as described later.Moreover, it becomes possible to output retrieved video datacorresponding to object movement information to the output device.Herein, video data corresponding to object movement information is videodata in which a person moving in segment regions indicated by objectmovement information is recorded, and is video data from which theobject movement information acquisition part 11 has acquired the objectmovement information.

Further, the object movement information acquisition part 11 can beconfigured to transmit video data acquired from an external device suchas a monitoring camera to the video data and metadata DB 12. Herein, thevideo processing device 1 may be configured to transmit video dataacquired from an external device to the video data and metadata DB 12not via the object movement information acquisition part 11.

The video data and metadata DB 12 is configured by, for example, astorage device such as a hard disk or a RAM (Random Access Memory), andstores various kinds of data. Herein, data stored by the video data andmetadata DB 12 is object movement information and video data. In thisexemplary embodiment, the video data and metadata DB 12 associates andstores object movement information and video data corresponding to theobject movement information.

The video data and metadata DB 12 receives video data received from anexternal device such as a monitoring camera by, for example, receivingvideo data transmitted by the object movement information acquisitionpart 11. Then, the video data and metadata DB 12 stores the receivedvideo data. The video data and metadata DB 12 also acquires objectmovement information transmitted by the object movement informationacquisition part 11. Then, the video data and metadata DB 12 associatesand stores object movement information and video data corresponding tothe object movement information. The video data and metadata DB 12 thusstores video data and object movement information associated with thevideo data.

Further, the video data and metadata DB 12 transmits the object movementinformation and video data stored therein to the metadata check part 14or the output device in response to a request by the metadata check part14. The details of retrieval of the object movement information storedin the video data and metadata DB 12 by the metadata check part 14 willbe described later.

In a case where the object movement information acquisition part 11 isconfigured to transmit time information and place information, the videodata and metadata DB 12 stores the time information and the placeinformation together with object movement information.

The retrieval condition input part 13 has a function of inputtingsegment regions and the sequence of the segment regions as retrievalconditions. To be specific, the retrieval condition input part 13includes an input device such as a touchscreen or a keyboard, and isconfigured so that it is possible to input retrieval conditions byoperating the input device. Input of retrieval conditions into theretrieval condition input part 13 is conducted by selecting segmentregions displayed on a screen with a mouse, for example. In this case,retrieval conditions are the selected segment regions and the sequenceof selection of the segment regions. Alternatively, input of retrievalconditions into the retrieval condition input part 13 is conducted bydrawing a line representing the trajectory of a retrieval target personon a screen where segment regions are shown as the background, forexample. In this case, retrieval conditions are segment regions wherethe drawn line passes and the sequence of passage. After that, theretrieval condition input part 13 transmits the inputted retrievalconditions to the metadata check part 14. Then, retrieval of objectmovement information based on the retrieval conditions is performed bythe metadata check part 14.

The metadata check part 14 has a function of searching object movementinformation (metadata) stored in the video data and metadata DB 12 basedon retrieval conditions received from the retrieval condition input part13.

To be specific, the metadata check part 14 receives retrieval conditionsincluding segment regions and the sequence of the segment regions fromthe retrieval condition input part 13. Subsequently, the metadata checkpart 14 performs retrieval from among object movement information storedin the video data and metadata DB 12 by using the received retrievalconditions.

Herein, the metadata check part 14 can be configured to retrieve onlyobject movement information identical to the retrieval conditions(identical segment regions, identical sequence) from the video data andmetadata DB 12. Alternatively, the metadata check part 14 can beconfigured to retrieve object movement information identical and/orsimilar to the retrieval conditions from the video data and metadata DB12.

Similarity of retrieval conditions and object movement information canbe determined by calculating a distance between the arrangement ofsegment regions (segment regions and the sequence of the segmentregions) represented by the retrieval conditions and the arrangement ofsegment regions represented by the object movement information, forexample. Meanwhile, it is possible to configure the metadata check part14 so as to determine whether or not retrieval conditions and objectmovement information are similar to each other by using a variety ofgeneral criterions for determining similarity other than theabovementioned method.

Further, the metadata check part 14 has a function of transmitting videodata stored in association with the retrieved object movementinformation to the output device such as the monitor. In other words,the metadata check part 14 receives video data stored in associationwith the object movement information retrieved from the video data andmetadata DB 12, and transmits the video data to the output device suchas the monitor.

That is the configuration of the video processing device 1. Byconfiguring the video processing device 1 as described above, it becomespossible to retrieve video images which show a person moving in desiredsegment regions in a desired sequence from among video images stored bythe video processing device 1. In other words, it becomes possible tocompletely retrieve video images of a person or the like moving from aspecific region to another specific region without considering amovement path in the regions (in the respective segment regions). Next,the operation of the video processing device 1 according to thisexemplary embodiment will be described.

An operation on acquiring object movement information (metadata) fromvideo data acquired from the external device such as the monitoringcamera and storing the object movement information and the video datawill be described.

Upon acquisition of video data from the monitoring camera or the like,the object movement information acquisition part 11 of the videoprocessing device 1 starts execution of a process shown in FIG. 3. Theobject movement information acquisition part 11 separates a monitoringtarget area in an image of the received video data into a plurality ofsegment regions determined in advance, and detects a person (a movingobject) moving in the segment regions (step S101).

Subsequently, the object movement information acquisition part 11acquires, as object movement information (i.e., metadata), movementsegment region information indicating segment regions where the detectedperson moves and segment region sequence information indicating thesequence of the segment regions corresponding to the movement of thedetected person (step S102).

Then, the object movement information acquisition part 11 transmits theacquired object movement information to the video data and metadata DB12. Also, the object movement information acquisition part 11 transmitsthe video data to the video data and metadata DB 12. The video data andmetadata DB 12 receives the object movement information and the videodata transmitted by the object movement information acquisition part 11.Then, the video data and metadata DB 12 associates and stores the objectmovement information and the video data corresponding to the objectmovement information (step S103).

Through such an operation, the video processing device 1 stores segmentregions where a person moves and the sequence of the segment regions asmetadata (object movement information). The metadata is stored inassociation with corresponding video data. Next, an operation onretrieving a video image showing a person moving in desired segmentregions in a desired sequence from among the video images stored by thevideo processing device 1 will be described.

Referring to FIG. 4, segment regions showing movement of a retrievaltarget object to be retrieved and the sequence of the segment regionsare inputted into the retrieval condition input part 13 (step S201).Then, the retrieval condition input part 13 into which retrievalconditions have been inputted transmits the retrieval conditions to themetadata check part 14.

Subsequently, the metadata check part 14 receives the retrievalconditions transmitted by the retrieval condition input part 13. Then,the metadata check part 14 uses the received retrieval conditions andretrieves object movement information identical (otherwise, identicaland/or similar) to the retrieval conditions from among the objectmovement information stored by the video data and metadata DB 12 (stepS202). After that, the metadata check part 14 acquires video data storedin association with the retrieved object movement information, andoutputs the acquired video data to the output device such as the monitor(step S203).

Through such an operation, the video processing device 1 can outputvideo data showing a person moving in desired segment regions in adesired sequence from among the video data stored in the videoprocessing device 1.

The video processing device 1 according to this exemplary embodimentthus includes the object movement information acquisition part 11 andthe video data and metadata DB 12. With this configuration, the objectmovement information acquisition part 11 of the video processing device1 detects a person moving in a plurality of segment regions in videodata acquired from outside, and acquires object movement informationcomposed of movement segment region information and segment regionsequence information. Then, the video data and metadata DB 12 stores theobject movement information and the video data. In other words, thevideo processing device 1 can store metadata (object movementinformation) which indicate segment regions where a person in video datamoves and the sequence of the segment regions. Moreover, the videoprocessing device 1 according to this exemplary embodiment includes theretrieval condition input part 13 and the metadata check part 14. Thisconfiguration enables input of retrieval conditions composed of segmentregions and the sequence of the segment regions into the retrievalcondition input part 13, and enables the metadata check part 14 tosearch metadata (object movement information) stored in the video dataand metadata DB 12 based on the retrieval conditions. As a result, itbecomes possible to completely retrieve video images of a person or thelike moving from a specific region to another specific region withoutconsidering a movement path in the regions.

For example, in a case where a person in a segment region C shown inFIG. 5 moves to a segment region B, various trajectories such as a routea and a route b are possible. However, according to the presentinvention, regarding both the route a and the route b, the objectmovement information acquisition part 11 acquires segment regions andthe sequence of the segment regions, namely, metadata (object movementinformation) representing that the person moves in segment regions C, Dand B in the sequence C→D→B. Thus, when segment regions and the sequenceof the segment regions are inputted into the retrieval condition inputpart 13 and retrieval by the metadata check part 14 is performed, it ispossible to completely retrieve video images of a person or the likemoving from a specific region to another specific region even ifmovement paths on which the person moving from the specific region tothe other specific moves are different, for example, the route a and theroute b.

In this exemplary embodiment, the video processing device 1 includes thevideo data and metadata DB 12. However, the video processing device 1may be configured to store video data and metadata (object movementinformation) into separate places.

Further, in this exemplary embodiment, the video processing device 1 isconfigured to separate a monitoring target area in an image of videodata into a plurality of segment regions and then detect a movingperson. However, the video processing device 1 may be configured todetect a moving person before separating a monitoring target area into aplurality of segment regions.

Further, the video processing device 1 according to this exemplaryembodiment may be configured to, when a detected person is in a givenstate determined in advance, include information indicating the givenstate (e.g., trajectory state information) into object movementinformation. Herein, a given state determined in advance is a givenstate such as wandering or fast movement. For example, when a detectedperson is in a given state such as repeatedly moving back and forth inthe same segment region, the object movement information acquisitionpart 11 of the video processing device 1 determines that the detectedperson is in the wandering state, and adds information indicating thewandering state to object movement information. However, theabovementioned given state is not limited to wandering, fast movementand the like, and a variety of states may be included into objectmovement information. For example, when a plurality of persons aredetected at the same time in the same segment region, object movementinformation acquired from the respective persons may be associated witheach other. Further, (the object movement information acquisition part11 of) the video processing device 1 may be configured to determinewhether or not a person is in a given state for each segment region, forexample.

In this exemplary embodiment, the single video processing device 1includes two means, namely, a video data storing means for acquiringobject movement information from video data and storing the objectmovement information, and a video data retrieving means for retrievingvideo data. However, the present invention is not limited to the videoprocessing device 1 having such a configuration. For example, thepresent invention may be realized by two information processing devices,namely, an information processing device including the video datastoring means and an information processing device including the videodata retrieving means. In this case, the information processing deviceincluding the video data retrieving means has, for example: a video dataretrieval part which acquires, as retrieval conditions, segment regioninformation of a plurality of segment regions obtained by separating amonitoring target area and sequence information of the passage sequenceof a moving object in the segment regions, and retrieves video data of amoving object meeting the acquired retrieval conditions; and a videodata output part which outputs the video data acquired by the video dataretrieval part. Thus, the present invention may be realized by aplurality of information processing devices.

Further, acquisition of object movement information from video datareceived from an external device (a video data acquiring means) such asa monitoring camera may be performed at any timing. For example, theobject movement information acquisition part 11 may acquire objectmovement information at the timing of acquisition of video data.Acquisition of object movement information may be performed at thetiming of input of retrieval conditions.

Second Exemplary Embodiment

Referring to FIGS. 6 and 7, a video processing device 2 according to asecond exemplary embodiment of the present invention is a device whichstores video images shot by a plurality of monitoring cameras, andretrieves desired video images from among the stored video images andoutputs the desired video images to an output device such as a monitor.In specific, a case where the whole shooting ranges of the respectivemonitoring cameras each form one segment region will be described inthis exemplary embodiment. Moreover, a case of acquiring object movementinformation additionally including the abovementioned given state willbe described in detail in this exemplary embodiment.

Referring to FIG. 8, the video processing device 2 according to thesecond exemplary embodiment of the present invention has a trajectoryinformation acquisition part 3 (a trajectory information acquiringmeans), an object movement information acquisition part 4, a metadataaccumulation part 5, a retrieval condition input part 6, a metadatacheck part 7, and a video data accumulation part 8. The object movementinformation acquisition part 4 has a segment region and path definingpart 41, and a trajectory information and segment region associatingpart 42. The retrieval condition input part 6 has a query input part 61and a gesture recognition part 62. Herein, the video processing device 2is an information processing device including an arithmetic device and astorage device. The video processing device 2 realizes the respectivefunctions described above by execution of a program stored in thestorage device by the arithmetic device.

The trajectory information acquisition part 3 has a function ofacquiring a plurality of video data from outside and detecting thetrajectory of a person moving in the plurality of video data. Referringto FIG. 9, the trajectory information acquisition part 3 has a videodata reception part 31 and a trajectory information detection part 32.

The video data reception part 31 has a function of receiving video datafrom an external device such as a monitoring camera. As shown in FIG. 9,in this exemplary embodiment, a plurality of monitoring cameras areinstalled at given positions, and the plurality of monitoring camerasare connected to the video data reception part 31 via an externalnetwork. Therefore, the video data reception part 31 acquires videoimages shot by the plurality of monitoring cameras installed at thegiven positions via the external network. Then, the video data receptionpart 31 executes preprocessing which is necessary for detection oftrajectory information by the trajectory information detection part 32,and then, transmits the plurality of video data to the trajectoryinformation detection part 32.

The video data reception part 31 also has a function of transmittingreceived video data to the video data accumulation part 8. As describedlater, video data transmitted to the video data accumulation part 8 isused at the time of output of video data to the output device.

The trajectory information detection part 32 has a function of detectinga person moving in video data of a plurality of spots shot by themonitoring cameras installed at the plurality of spots, and detectingthe trajectory of the detected person. As described above, in thisexemplary embodiment, the whole image of a video shot by one monitoringcamera is considered as one segment region. Therefore, the trajectoryinformation detection part 32 detects a person moving in a plurality ofsegment regions, and detects the trajectory of the person moving in theplurality of segment regions.

The trajectory information detection part 32 receives video datatransmitted by the video data reception part 31. Otherwise, thetrajectory information detection part 32 acquires video data accumulatedin the video data acquisition part 8. Then, the trajectory informationdetection part 32 detects a person moving in video data of a pluralityof spots by using the video data received from the video data receptionpart 31 and video data acquired from the video data accumulation part 8.

For example, referring to FIG. 7, the trajectory information detectionpart 32 acquires video data A, video data a, and video data B. Then, thetrajectory information detection part 32 detects the same person movingin the video data A, the video data a, and the video data B. A personmoving in a plurality of video data can be detected by using a varietyof techniques. For example, it is possible to: perform face recognitionof persons and detect persons from who the same data is obtained as thesame person; or recognize as the same person by clothes recognition. Inother words, when persons recognized to have the same faces or be in thesame clothes appear in the respective video data A, a and B, thetrajectory information detection part 32 recognizes, as the same person,the persons recognized to have the same faces or be in the same clothesappearing in the respective video data A, a and B. Alternatively, it isalso possible to previously determine a general elapsed time for passingthrough one image and then appearing in another image and, when a personsatisfying the previously determined elapsed time is detected, recognizeas the same person, for example. Other than the abovementioned methods,a variety of general methods may be used.

Then, the trajectory information detection part 32 detects, astrajectory information, the trajectory of a person moving in a pluralityof video data detected by the abovementioned method. Detection of thetrajectory of a person by the trajectory information detection part 32can also be performed by using a variety of techniques. For example, itis possible to extract the same person from the respective image framesof a plurality of video data, and connect the extracted persons with aline. Other than the abovementioned methods, a variety of generalmethods may be used.

Thus, the trajectory information detection part 32 detects a personmoving in a plurality of video data, and detects the trajectory of theperson moving in the plurality of video data as trajectory information.Then, the trajectory information detection part 32 transmits thedetected trajectory information to the trajectory information andsegment region associating part 42.

In this exemplary embodiment, a case of acquiring three video data anddetecting a person moving in the three video data (in three segmentregions) has been described referring to FIG. 7. However, the trajectoryinformation detection part 32 is not limited to the abovementioned case,and can acquire a plurality of video data and detect a person moving ina plurality of video data, for example, acquire four video data anddetect a person moving in two of the four video data.

Trajectory information includes information for identifying video datafrom which the trajectory information is detected. Trajectoryinformation may further include information for recognizing a part whichshows a person moving in a segment region and is indicated by trajectoryinformation in each of a plurality of video data. Trajectory informationmay include time information indicating time when a person passesthrough each spot on a trajectory indicated by the trajectoryinformation (e.g., a movement start spot and a movement end spot in eachsegment region), and place information indicating the shooting place ofa video data from which the trajectory information is acquired(indicating the place of a segment region).

The object movement information acquisition part 4 has a function ofusing trajectory information and acquiring object movement informationcomposed of movement segment region information and segment regionsequence information. As mentioned above, the object movementinformation acquisition part 4 has the segment region and path definingpart 41 and the trajectory information and segment region associatingpart 42.

The segment region and path defining part 41 has a function ofgenerating segment region and path information which defines segmentregions and path information indicating connection of the segmentregions. In other words, the segment region and path defining part 41generates segment region and path information composed of segmentregions as a plurality of video data and path information indicatingconnection of the segment regions. Then, the segment region and pathdefining part 41 transmits the generated segment region and pathinformation to the trajectory information and segment region associatingpart 42 and the retrieval condition input part 6. Segment region andpath information may be defined in advance. As mentioned above, in thisexemplary embodiment, the segment region and path defining part 41defines each of the whole shooting ranges of the respective monitoringcameras as one segment region. Moreover, connection of places shot bythe respective monitoring cameras is defined as path information.

The trajectory information and segment region associating part 42 has afunction of using trajectory information and segment region and pathinformation to acquire object movement information. In other words, thetrajectory information and segment region associating part 42 associatestrajectory information with segment region and path information, andthereby acquires, as object movement information, movement segmentregion information indicating segment regions where a person indicatedby a trajectory moves and segment region sequence information indicatingthe sequence of the segment regions corresponding to the movement of theperson. In this exemplary embodiment, as mentioned above, the wholeshooting ranges of the plurality of monitoring cameras are each definedas one segment region. Therefore, referring to FIG. 7 as an example, thetrajectory information and segment region associating part 42 acquiresobject movement information corresponding to the shooting ranges of therespective video data and indicating that a person passes through thesegment regions A, a and B in the sequence A→a→B.

The trajectory information and segment region associating part 42 alsohas a function of determining whether or not the state of a trajectoryin each segment region is a given state determined in advance. In otherwords, after associating the trajectory information with the segmentregion and path information, the trajectory information and segmentregion associating part 42 determines whether or not the trajectory ineach of the segment regions is a given state determined in advance.

Herein, a given state determined in advance is a given state such aswandering or fast movement. Referring to FIG. 10 as an example, it isfound that a detected person repeatedly moves back and forth in thesegment region A. Thus, when the state of a trajectory indicated bytrajectory information in a segment region (in the segment region A inFIG. 10) is a given state such as a state where a person moves back andforth a specified number of times or more or a state where a personstays in the segment region for a given time or more, the trajectoryinformation and segment region associating part 42 determines that theperson is in the wandering state. Then, the trajectory information andsegment region associating part 42 acquires object movement informationadditionally including information (trajectory state information)indicating that the trajectory in the segment region A is in thewandering state.

Other than the wandering state, when a trajectory indicated bytrajectory information of a segment region shows a state that a personpasses fast through the segment region, the trajectory information andsegment region associating part 42 can add information indicating a fastmovement state (trajectory state information) to object movementinformation. For example, by using segment regions, trajectoryinformation, and time information, the trajectory information andsegment region associating part 42 can determine whether or not atrajectory (movement of a person) in the segment region is fast.

Besides, in a case where a plurality of trajectories exist at the sametime in the same segment region, the trajectory information and segmentregion associating part 42 can associate trajectory informationindicating the trajectories with each other. In other words, thetrajectory information and segment region associating part 42 can addinformation which associates trajectory information indicatingtrajectories existing at the same time in the same segment region witheach other, to corresponding object movement information. The trajectoryinformation and segment region associating part 42 can also addinformation including the states of the trajectories to the objectmovement information. Referring to FIG. 11 as an example, it is foundthat a plurality of persons are moving together. Then, in a case wherethe trajectories of the plurality of persons are within a predetermineddistance, the trajectory information and segment region associating part42 adds information representing that the persons are moving together(trajectory state information) to the respective object movementinformation. Further, referring to FIG. 12 as an example, it is foundthat a plurality of persons are moving separately in the segment regionA. Then, in a case where the trajectories of the plurality of persons inthe section A are apart a predetermined distance or more, the trajectoryinformation and segment region associating part 42 adds informationrepresenting that the persons are moving separately in the segmentregion A (trajectory state information) to the respective objectmovement information.

The trajectory information and segment region associating part 42 canalso add information including the direction of a trajectory to objectmovement information. Although the examples of trajectory stateinformation have been described above, the present invention allowsaddition of a variety of trajectory states other than the abovementionedones to object movement information.

Thus, the trajectory information and segment region associating part 42acquires not object movement information indicating only a trajectory ineach segment region but object movement information additionallyincluding trajectory state information indicating a given state of thetrajectory when the trajectory is in the given state. The trajectoryinformation and segment region associating part 42 determines whether ornot a trajectory is in a given state, for each segment region.

Object movement information includes information for identifying aplurality of video data included in trajectory information from whichthe object movement information is acquired. Object movement informationmay also include time information and place information.

As described above, the trajectory information and segment regionassociating part 42 acquires object movement information (metadata) byusing trajectory information and segment region and path information.Then, the trajectory information and segment region associating part 42transmits the trajectory information and the object movement informationto the metadata accumulation part 5. Meanwhile, the trajectoryinformation and segment region associating part 42 may be configured totransmit only the object movement information to the metadataaccumulation part 5.

The metadata accumulation part 5 is configured by, for example, astorage device such as a hard disk or a RAM (Random Access Memory), andstores trajectory information and object movement information. In otherwords, the metadata accumulation part 5 receives trajectory informationand object movement information transmitted from the trajectoryinformation and segment region associating part 42. Then, the metadataaccumulation part 5 stores the received trajectory information andobject movement information. After that, the metadata accumulation part5 transmits the object movement information (metadata) stored thereby inresponse to a request by the metadata check part 7 as described later.In a case where the trajectory information and segment regionassociating part 42 is configured to transmit only the object movementinformation, the metadata accumulation part 5 stores only the objectmovement information.

The retrieval condition input part 6 has a function of inputting segmentregions and the sequence of the segment regions, as retrievalconditions. As mentioned above, the retrieval condition input part 6 hasthe query input part 61 and the gesture recognition part 62.

The query input part 61 has a function of inputting a query forretrieving object movement information (metadata) stored in the metadataaccumulation part 5 and generating query information based on the query.The query input part 61 in this exemplary embodiment has a touchscreen,and a query is inputted by drawing a line on a background correspondingto a segment region displayed on the touchscreen.

Herein, query information indicates an input of a line or successivedots. Although a touchscreen is used to input a line in this exemplaryembodiment, it is also possible to use a variety of items which candepict a line other than the touchscreen. For example, it is possible touse a mouse. Then, as described later, an inputted line, the directionof drawing the line, the number of strokes with which a connected lineis written, and the number of the drawn lines are collected as queryinformation.

For example, as mentioned above, input of query information through thequery input part 61 is conducted by drawing a line on the backgroundcorresponding to a segment region displayed on the touchscreen. In otherwords, the user selects a range or the like (a segment region) where theuser wants to input query information (wants to conduct retrieval), asthe background. Then, the user draws a line in the selected range(otherwise, draws in part of the displayed background). Moreover, theuser then conducts a given operation determined in advance, therebyinputting trajectory state information. Trajectory state information isdetermined for each segment region. Therefore, necessary trajectorystate information is inputted into the query input part 61 for eachtrajectory information.

An example of a given operation performed when inputting trajectorystate information into the query input part 61 will be described. FIGS.13α to ε will be referred to. FIG. 13α shows an operation performed wheninputting trajectory state information representing that a person iswandering. FIG. 13β shows an operation performed when inputtingtrajectory state information representing that a person is moving fast.FIG. 13γ shows an operation performed when inputting trajectory stateinformation representing that a plurality of persons are movingtogether. FIG. 13δ shows an operation performed when inputtingtrajectory state information representing that a plurality of personsare moving separately in a segment region A and moving together insegment regions a and B. FIG. 13ε shows an operation performed wheninputting trajectory state information representing that there is aperson moving in the opposite direction.

As shown in Fig. α, for inputting trajectory state informationrepresenting that a person is wandering, a line is drawn circularlyseveral times, for example. By thus inputting, as described later, it ispossible to input trajectory state information representing that aperson is wandering in a segment region (the segment region A in FIG.13α) including a part where the line is drawn circularly several times.Moreover, as shown in Fig. β, for inputting trajectory state informationrepresenting that a person is moving fast, a line is drawn circularlyone time, for example. By thus inputting, it is possible to inputtrajectory state information representing that a person is moving fastin a segment region (the segment region A in FIG. 13β) including a partwhere the line is drawn circularly one time. Moreover, as shown in Fig.γ, by drawing a plurality of lines close to each other, it is possibleto input trajectory state information representing that a plurality ofpersons are moving together. Moreover, as shown in Fig. δ, by separatingthe plurality of lines as drawn in FIG. 13γ at a predetermined intervalor more, it is possible to input trajectory state informationrepresenting that a plurality of persons are moving separately in asegment region including a part where the plurality of lines are drawnat the predetermined interval or more. Moreover, as shown in Fig. ε, bydrawing a line directing in the opposite direction, it is possible toinput trajectory state information representing that there is a personmoving in the opposite direction.

In a query inputted into the query input part 61, the direction isdetermined based on the drawing order. Moreover, the abovementionedqueries can be combined with each other. For example, referring to FIG.14, it is possible to draw a state where a person moving in the oppositedirection is moving fast.

Further, it is possible to use an AND condition and an OR condition bydrawing with a single stroke and drawing with two or more strokes. Forexample, referring to FIG. 15, inputting a query with a single stroke isdrawing a state where a person moves fast in the segment region A andalso moves fast in the segment region B. On the other hand, inputting aquery with two strokes is drawing a state where a person moves fast inthe segment region A or moves fast in the segment region B.Alternatively, an AND condition and an OR condition may be depicted by,for example, drawing with three or more strokes, or drawing with asingle stroke multiple times to draw a plurality of queries.

By thus drawing a specific figure in line drawing, it is possible toinput trajectory state information. However, the present invention maybe practiced not limited to input of trajectory state information by theabovementioned method. For example, it is possible to employ a varietyof methods such as select desired trajectory state information from amenu displayed when stopping drawing for a given time in line drawing.

The query input part 61 to which query information has been inputted bythe abovementioned method transmits the query information to the gesturerecognition part 62.

The gesture recognition part 62 has a function of associating queryinformation received from the query input part 61 with segment regionand path information received from the segment region and path definingpart 41 and thereby recognizing trajectory state information (a gesture)expressed by a query for each segment region. The gesture recognitionpart 62 also has a function of associating the query information withthe segment region and path information and thereby acquiring segmentregions where the query passes and the sequence of the segment regions(as retrieval conditions).

In other words, the gesture recognition part 62 uses query informationand segment region and path information and thereby acquire gestureinformation representing trajectory state information (a gesture) foreach segment region, segment regions, and the sequence of the segmentregions. Then, the gesture recognition part 62 transmits the acquiredretrieval conditions to the metadata check part 7.

The gesture recognition part 62 may have a function of feeding back agesture recognized by the gesture recognition part 62. To be specific,the gesture recognition part 62 may cause the query input part 61including a display function to display a mark or a symbol associatedwith each gesture set in advance. For example, in a case where an inputand an output are the same as shown in FIG. 16 (for example, in a casewhere the background and the drawn line are displayed on thetouchscreen), for a line drawn by the user (as query information), asymbol indicating wandering is displayed on the touchscreen as the ofrecognition of a gesture by the gesture recognition part 62. Besides,for example, it is possible to configure so that the user can tap thedisplayed symbol and thereby input detailed information on the state ofthe trajectory corresponding to the symbol (in FIG. 16, the wanderingstate). For example, in FIG. 16, the range of a wandering time isdesignated.

The metadata check part 7 has a function of retrieving object movementinformation (metadata) stored in the metadata accumulation part 5 basedon a retrieval condition received from the retrieval condition inputpart 6. The metadata check part 7 may also have a function of acquiringvideo data relating to the retrieved object movement information fromthe video data accumulation part 8 and outputting the retrieval resultto an output device such as a monitor.

The metadata check part 7 receives a retrieval condition from theretrieval condition input part 6. Then, the metadata check part 7retrieves object movement information stored in the metadataaccumulation part 5 by using the received retrieval condition. Afterthat, the metadata check part 7 acquires video data relating to theretrieved object movement information (video data in which a personindicated by the object movement information is recorded) from the videodata accumulation part 8, and transmits the acquired video data to anoutput device such as a monitor.

Herein, the metadata check part 7 may be configured to retrieve onlyobject movement information identical to the retrieval condition fromthe metadata accumulation part 5, for example. The metadata check part 7may be configured to retrieve object movement information identicaland/or similar to the retrieval condition from the metadata accumulationpart 5, for example.

Determination of similarity by the metadata check part 7 may beperformed by the same configuration as already described. The metadatacheck part 7 may also be configured to determine similarity inconsideration of trajectory state information.

The video data accumulation part 8 is configured by, for example, astorage device such as a hard disk and a RAM (Random Access Memory), andstores video data. In other words, the video data accumulation part 8receives video data transmitted from the video data reception part 31.Then, the video data accumulation part 8 stores the received video data.After that, the video data accumulation part 8 transmits video datacorresponding to object movement information to the output device inresponse to a request by the metadata check part 7 to be describedlater.

That is the configuration of the video processing device 2. With theabovementioned configuration, the video processing device 2 can retrievea video image showing a person moving in desired segment regions in adesired sequence from among the stored video images. Next, an operationof the video processing device 2 according to this exemplary embodimentwill be described.

An operation performed when acquiring object movement information(metadata) from video data acquired from outside, for example, from amonitoring camera and storing the object movement information and thevideo data will be described.

When the video data reception part 31 of the video processing device 2receives video data via an external network from a plurality ofmonitoring cameras installed at external given positions, execution of aprocess shown in FIG. 17 is started. The video data reception part 31transmits the received video data of the plurality of spots to thetrajectory information detection part 32. Then, the trajectoryinformation detection part 32 detects a person moving in the video dataof the plurality of spots and detects the trajectory of the detectedperson. Consequently, the trajectory information detection part 32detects trajectory information indicating the trajectory of the personmoving in the video data of the plurality of spots (step S301).

Subsequently, the trajectory information detection part 32 transmits thedetected trajectory information to the trajectory information andsegment region associating part 42. Also, segment region and pathinformation defined by the segment region and path defining part 41 istransmitted to the trajectory information and segment region associatingpart 42. Then, the trajectory information and segment region associatingpart 42 associates the trajectory information with the segment regionand path information and thereby acquires object movement information(creates metadata) (step S302). Herein, object movement informationincludes segment regions, the sequence of the segment regions, andtrajectory state information of each of the segment regions.

Subsequently, the trajectory information and segment region associatingpart 42 transmits the object movement information to the metadataaccumulation part 5. After that, the metadata accumulation part 5 storesthe object movement information as metadata (step S303).

By performing the abovementioned operation, the video processing device2 stores segment regions where a person moves, the sequence of thesegment regions, and trajectory state information of each of the segmentregions, as metadata (object movement information). The metadata isstored in association with corresponding video data. Next, an operationperformed when retrieving a video image showing a person moving indesired segment regions in a desired sequence from among video imagesstored in the video processing device 2.

Referring to FIG. 18, query information is inputted into the query inputpart 61 of the retrieval condition input part 6 (step S401).Subsequently, the query input part 61 transmits the inputted queryinformation to the gesture recognition part 62.

Next, the gesture recognition part 62 receives the query information.The gesture recognition part 62 also receives segment region and pathinformation from the segment region and path defining part 41. Then, thegesture recognition part 62 reads a predetermined figure from theinputted query information, and recognizes a gesture included in thequery information (step S402). Moreover, the gesture recognition part 62associates the recognized gesture with the segment region and pathinformation and thereby acquires gesture information for each segmentregion (step S403). Furthermore, the gesture recognition part 62associates the query information with the segment region and pathinformation and thereby acquires segment regions where the query passesand the sequence of the segment regions (as retrieval conditions).Consequently, the gesture recognition part 62 acquires retrievalconditions composed of the segment regions, the sequence of the segmentregions, and the gesture (object movement information) of each of thesegment regions (step S404). Then, the gesture recognition part 62transmits the acquired retrieval conditions to the metadata check part7. Acquisition of segment regions and the sequence of the segmentregions by the gesture recognition part 62 may be performed beforeacquisition of gesture information.

After that, the metadata check part 7 receives the retrieval conditionstransmitted by the gesture recognition part 62. Then, the metadata checkpart 7 retrieves object movement information identical and/or similar tothe retrieval conditions from among the object movement informationstored in the metadata accumulation part 5 (step S405). Then, themetadata check part 7 acquires video data corresponding to the retrievedobject movement information from the video data accumulation part 8, andoutputs the acquired video data to an output device such as a monitor(step S406).

By performing such an operation, the video processing device 2 canoutput video data showing a person moving in desired segment regions ina desired sequence from among video data stored in the video processingdevice 2.

As described above, the video processing device 2 according to thisexemplary embodiment includes the trajectory information acquisitionpart 3, the object movement information acquisition part 4, the metadataaccumulation part 5, the retrieval condition input part 6, the metadatacheck part 7, and the video data accumulation part 8. According to thisconfiguration, the trajectory information acquisition part 3 of thevideo processing device 2 detects a person moving in a plurality ofvideo data and detects the trajectory of the moving person. Then, theobject movement information acquisition part 4 of the video processingdevice 2 can acquire object movement information based on the detectedtrajectory and store the object movement information into the metadataaccumulation part 5. Moreover, by input of a retrieval condition intothe retrieval condition input part 6, the metadata check part 7 of thevideo processing device 2 can search the object movement informationstored by the accumulation part 5. This configuration enables retrievalunder inputted retrieval conditions composed of segment regions and thesequence of the segment regions, and allows complete retrieval of videoimages showing a person or the like moving from a specific region toanother specific region without considering a movement path in theregions.

Further, the video processing device 2 according to this exemplaryembodiment includes the segment region and path defining part 41, thetrajectory information and segment region associating part 42, the queryinput part 61, and the gesture recognition part 62. This configurationenables the trajectory information and segment region associating part42 to acquire the state of a trajectory for each segment region definedby the segment region and path defining part 41. Moreover, by input of aquery additionally including the state of a trajectory into the queryinput part 61, the gesture recognition part 62 can acquire the state ofa trajectory of each segment region. This configuration enablesretrieval of proper video data with addition of the state of atrajectory in each segment region.

Third Exemplary Embodiment

In this exemplary embodiment, a case where the segment region and pathdefining part 41 defines segment regions in a different way from in thesecond exemplary embodiment will be described.

A video processing device in this exemplary embodiment has the sameconfiguration as in the second exemplary embodiment. Description of eachcomponent has already been made, and therefore, will be omittedhereinafter.

Referring to FIG. 19, the video processing device in this exemplaryembodiment acquires a plurality of video data. In this exemplaryembodiment, the segment region A is separated into four segment regionsAa, Ab, Ac and Ad, and the segment region B is separated into twosegment regions Ba and Bb.

As illustrated in this exemplary embodiment, the segment region and pathdefining part 41 may be configured not to necessarily define each of thewhole shooting ranges of the monitoring cameras as one segment region.For example, the segment region and path defining part 41 may furtherseparate a monitoring target area in an image of one video data into aplurality of segment regions in the same manner as separating the videodata A. Moreover, the segment region and path defining part 41 maychange, depending on video data, the number of segment regions obtainedby separating a monitoring target area in an image of the video data.

Thus, the segment region and path defining part 41 in this exemplaryembodiment may be configured to, when separating monitoring target areasin images of a plurality of video data into a plurality of segmentregions, further separate the monitoring target area in the image ofeach of the video data into a plurality of segment regions, instead ofsetting a segment region for each video data. Consequently, it becomespossible to define segment regions close to the realities, for example,define segment regions in accordance with the frequency of passage of aperson.

The definition of segment regions by the segment region and pathdefining part 41 may be changed in accordance with the magnification ofthe background displayed on the touchscreen, for example. Referring toFIG. 20 as an example, in a state where the background is reduced, it isassumed that the whole shooting range of each of the monitoring camerasis one segment region (e.g., a monitoring target area is separated intothe segment region A, the segment region a, and the segment region B).On the other hand, in a state where the background is enlarged, it isassumed that there are four segment regions including the segmentregions Aa, Ab, Ac and Ad (the segment region A in the shrunk state isseparated into the segment region Aa, the segment region Ab, the segmentregion Ac, and the segment region Ad). Thus, the video processing devicemay be configured so that the object movement information acquisitionpart 4 generates object movement information (metadata) in accordancewith a magnification at which the background can be displayed and storesthe metadata into the metadata accumulation part 5 and retrieval can beperformed only by manipulating a magnification. This configurationenables detailed trajectory retrieval by segmentation of a segmentregion. The enlarging/shrinking operation may be performed by anymethod, for example, by using multi-touch gestures such as pinch in andpinch out or by using enlarging and shrinking buttons.

Next, a video processing system 9 capable of completely retrieving videoimages of a person or the like moving from a specific region to anotherspecific region will be described. In this exemplary embodiment, theoverview of the configuration of the video processing system 9 will bedescribed.

Fourth Exemplary Embodiment

Referring to FIG. 21, the video processing system 9 according to thefourth exemplary embodiment of the present invention has an objectmovement information acquiring means 91, an object movement informationand video data storing means 92, a retrieval condition inputting means93, and a video data retrieving means 94.

The object movement information acquiring means 91 has a function ofacquiring object movement information composed of movement segmentregion information and segment region sequence information from videodata obtained by shooting a monitoring target area. To be specific, theobject movement information acquiring means 91 receives video dataobtained by shooting a monitoring target area (for example, from one orplural video data acquiring means). Subsequently, the object movementinformation acquiring means 91 separates the monitoring target area intoa plurality of segment regions determined in advance, and detects aperson (a moving object) moving in a plurality of segment regions in thevideo data obtained by shooting the monitoring target area. Then, theobject movement information acquiring means 91 acquires, as objectmovement information, movement segment region information indicating thesegment regions where the detected person moves and segment regionsequence information indicating the sequence of the segment regionscorresponding to the movement of the detected person. After that, theobject movement information acquiring means 91 transmits the objectmovement information to the object movement information and video datastoring means 92.

The object movement information acquiring means 91 can acquire singlevideo data and separate a monitoring target area in an image of theacquired video data into a plurality of segment regions. Also, theobject movement information acquiring means 91 can acquire a pluralityof video data and define each of the shooting ranges of the plurality ofvideo data as a segment region, thereby separating monitoring targetareas in images of the plurality of video data into a plurality ofsegment regions. The object movement information acquiring means 91 canalso separate each of the monitoring target areas in the images of theplurality of acquired video data into a plurality of segment regions.

Because the details of segment regions, movement segment regioninformation, segment region sequence information and so on has alreadybeen described, description thereof will be omitted. Further, in thesame manner as already described, object movement information isconfigured so that video data corresponding to the object movementinformation can be retrieved.

For example, the object movement information and video data storingmeans 92 is configured by a hard disk, or the like. The object movementinformation and video data storing means 92 has a function ofassociating and storing object movement information and video data. Theobject movement information and video data storing means 92 receivesobject movement information transmitted by the object movementinformation acquiring means 91. Also, the object movement informationand video data storing means 92 receives video data acquired by theobject movement information acquiring means 91 via the object movementinformation acquiring means 91 or the like. Then, the object movementinformation and video data storing means 92 associates and stores theobject movement information and the video data corresponding to theobject movement information.

The retrieval condition inputting means 93 has a function of inputtingsegment regions showing movement of a retrieval target person and thesequence of the segment regions. The retrieval condition inputting means93 includes an input device such as a touchscreen or a keyboard. Then,through operation of the input device, a retrieval condition is inputtedinto the retrieval condition inputting means 93. After that, theretrieval condition inputting means 93 transmits the inputted retrievalcondition to the video data retrieving means 94.

The video data retrieving means 94 has a function of retrieving objectmovement information corresponding to a retrieval condition. The videodata retrieving means 94 receives retrieval conditions including segmentregions and the sequence of the segment regions from the retrievalcondition inputting means 93. Subsequently, the video data retrievingmeans 94 uses the received retrieval conditions to retrieve the objectmovement information stored in the object movement information and videodata storing means 92. Then, the video data retrieving means 94 outputsvideo data stored in association with the retrieved object movementinformation to an output device such as a monitor.

The video data retrieving means 94 may be configured to retrieve onlyobject movement information identical to a retrieval condition (the samesegment regions and the same sequence) from the object movementinformation and video data storing means 92. Alternatively, the videodata retrieving means 94 may be configured to retrieve object movementinformation identical and/or similar to a retrieval condition from theobject movement information and video data storing means 92.

That is the configuration of the video processing system 9. With theabovementioned configuration, the video processing system 9 can retrievea video image showing a person moving in desired segment regions in adesired sequence from among video images stored by the object movementinformation and video data storing means 92. In other words, it becomespossible to completely retrieve video images of a person or the likemoving from a specific region to another specific region withoutconsidering movement paths in the regions (in the respective segmentregions).

Next, a video processing device 10 capable of completely retrievingvideo images of a person or the like moving from a specific region toanother specific region will be described. In this exemplary embodiment,the overview of the configuration of the video processing device 10 willbe described.

Fifth Exemplary Embodiment

Referring to FIG. 22, the video processing device 10 according to afifth exemplary embodiment of the present invention has a video dataretrieval part 101 and a video data output part 102.

The video data retrieval part 101 has a function of acquiring, asretrieval conditions, segment region information of a plurality ofsegment regions obtained by dividing a monitoring area and sequenceinformation of the sequence of the segment regions through which amoving object passes, and retrieving video data of the moving objectmeeting the acquired retrieval conditions. In other words, the videodata retrieval part 101 acquires video data from a video data storagepart or from outside, and retrieves video data of a moving objectmeeting retrieval conditions from the acquired video data. Retrievalconditions which are conditions for retrieval performed by the videodata retrieval part 101 include segment region information of aplurality of segment regions obtained by dividing a monitoring area andsequence information of the sequence of the segment regions throughwhich a moving object passes

The video data output part 102 has a function of outputting video dataacquired by the video data retrieval part 101. The video data outputpart 102 is connected to an external device such as a monitor, andoutputs video data to the monitor or the like.

That is the configuration of the video processing device 10. Asdescribed above, the video processing device 10 includes the video dataretrieval part 101 and the video data output part 102. Retrievalconditions for retrieval performed by the video processing device 10include segment region information of a plurality of segment regionsobtained by dividing a monitoring target area and sequence informationof the sequence of the segment regions through which a moving objectpasses. With this configuration, the video processing device 10 canretrieve video data by using segment region information and sequenceinformation. As a result, the video processing device 10 can completelyretrieve video images of a person or the like moving from a specificregion to another specific region without considering movement paths inthe regions.

Further, the video processing device 10 described above can be realizedby installing a given program into the video processing device 10. To bespecific, a program as another aspect of the present invention is acomputer program for causing the video processing device to function as:a video data retrieval part which acquires, as retrieval conditions,segment region information of a plurality of segment regions obtained bydividing a monitoring target area and sequence information of thesequence of the segment regions through which a moving object passes,and retrieves video data of the moving object meeting the acquiredretrieval conditions; and a video data output part which outputs thevideo data acquired by the video data retrieval part.

Further, a method for video processing executed by operation of thevideo processing device 10 described above is a method including:acquiring, as retrieval conditions, segment region information of aplurality of segment regions obtained by dividing a monitoring targetarea and sequence information of the sequence of the segment regionsthrough which a moving object passes, and retrieving video data of themoving object meeting the acquired retrieval conditions; and outputtingthe retrieved video data.

The inventions of the program and the video processing method having theabovementioned configurations have the same actions as the videoprocessing device 10, and therefore, can achieve the object of thepresent invention.

<Supplementary Notes>

The whole or part of the exemplary embodiments disclosed above can bedescribed as the following supplementary notes. Below, the overview of avideo processing device and so on according to the present inventionwill be described. However, the present invention will not be limited tothe following configurations.

(Supplementary Note 1)

A video processing system comprising:

an object movement information acquiring means for detecting a movingobject from video data and acquiring movement segment region informationas object movement information, the video data being obtained byseparating a monitoring target area into a predetermined plurality ofsegment regions and shooting the monitoring target area, the movingobject moving in the plurality of segment regions, the movement segmentregion information representing segment regions where the detectedmoving object has moved;

an object movement information and video data storing means for storingthe object movement information in association with the video datacorresponding to the object movement information, the object movementinformation being acquired by the object movement information acquiringmeans;

a retrieval condition inputting means for inputting a sequence of thesegment regions as a retrieval condition, the segment regions showingmovement of a retrieval target object to be retrieved; and

a video data retrieving means for retrieving the object movementinformation in accordance with the retrieval condition and outputtingvideo data stored in association with the retrieved object movementinformation, the object movement information being stored by the objectmovement information and video data storing means, the retrievalcondition being inputted by the retrieval condition inputting means.

According to this configuration, the video processing system includes avideo data acquiring means, an object movement information acquiringmeans, a retrieval condition inputting means, and a video dataretrieving means. With this configuration, the video processing systemcan acquire object movement information (metadata) including movementsegment region information and segment region sequence information fromvideo data acquired by the video data acquiring means. Moreover, byinput of a retrieval condition into the retrieval condition inputtingmeans, the video data retrieving means can retrieve object movementinformation and output associated video data. As a result, it becomespossible to retrieve video data based on object movement information,and it becomes possible to completely retrieve video images of a personor the like moving from a specific region to another specific regionwithout considering movement paths in the regions.

(Supplementary Note 2)

The video processing system according to Supplementary Note 1, furthercomprising a trajectory information acquiring means for acquiring atrajectory as trajectory information from the video data, the trajectorybeing of movement of the moving object in the plurality of segmentregions,

wherein the object movement information acquiring means acquires theobject movement information by associating the trajectory with thepredetermined plurality of segment regions, the trajectory beingrepresented by the trajectory information acquired by the trajectoryinformation acquiring means.

According to this configuration, the video processing system includesthe trajectory information acquiring means. With this configuration, thevideo processing system can acquire object movement information based ontrajectory information acquired by the trajectory information acquiringmeans. As a result, it becomes possible to more efficiently acquireobject movement information.

(Supplementary Note 3)

The video processing system according to Supplementary Note 2, wherein:

in a case where a state of the trajectory represented by the trajectoryinformation is a predetermined given state, the object movementinformation acquiring means acquires the object movement informationadditionally including trajectory state information representing thegiven state; and

the retrieval condition inputting means is configured to input theretrieval condition additionally including the trajectory stateinformation.

According to this configuration, the object movement informationacquiring means acquires object movement information to which trajectorystate information indicating the state of a trajectory is added.Moreover, into the retrieval condition inputting means, retrievalconditions additionally including the state of the trajectory isinputted. With this configuration, it becomes possible to retrieve videodata in consideration of the state of the trajectory. As a result, itbecomes possible to retrieve video data meeting the conditions more.

(Supplementary Note 4)

The video processing system according to any of Supplementary Notes 1 to3, wherein the retrieval condition inputting means inputs the retrievalcondition by drawing a line on a background showing the predeterminedplurality of segment regions.

(Supplementary Note 5)

The video processing system according to Supplementary Note 4, whereinthe retrieval condition inputting means inputs the trajectory stateinformation by performing a predetermined given operation when drawing aline on a background showing the predetermined plurality of segmentregions.

(Supplementary Note 6)

The video processing system according to any of Supplementary Notes 1 to5, further comprising one or a plurality of video data acquiring meansfor acquiring video data of the monitoring target area.

(Supplementary Note 7)

A video processing device comprising:

a video data retrieval part configured to acquire segment regioninformation and sequence information as a retrieval condition andretrieve video data of a moving object, the segment region informationbeing of a plurality of segment regions obtained by dividing amonitoring target area, the sequence information being of a sequence ofthe segment regions where a moving object has passed, the video datameeting the acquired retrieval condition; and

a video data output part configured to output the video data acquired bythe video data retrieval part.

(Supplementary Note 8)

The video processing device according to Supplementary Note 7, furthercomprising a video data storage part configured to store video data,

wherein the video data retrieval part acquires the video data stored bythe video data storage part and retrieves video data of a moving object,the video data meeting the retrieval condition.

(Supplementary Note 9)

The video processing device according to Supplementary Note 8, furthercomprising an object movement information acquisition part configured todetect a moving object from video data and acquiring movement segmentregion information as object movement information, the video data beingobtained by separating a monitoring target area into a predeterminedplurality of segment regions and shooting the monitoring target area,the moving object moving in the plurality of segment regions, themovement segment region information representing segment regions wherethe detected moving object has moved,

wherein the video data storage part stores the object movementinformation in association with the video data corresponding to theobject movement information, the object movement information beingacquired by the object movement information acquisition part.

(Supplementary Note 10)

The video processing device according to Supplementary Note 9, furthercomprising a trajectory information acquisition part configured toacquire a trajectory as trajectory information from the video data, thetrajectory being of movement of the moving object in the plurality ofsegment regions,

wherein the object movement information acquisition part acquires theobject movement information by associating the trajectory with thepredetermined plurality of segment regions, the trajectory beingrepresented by the trajectory information acquired by the trajectoryinformation acquisition part.

(Supplementary Note 11)

The video processing device according to Supplementary Note 10, wherein:

in a case where a state of the trajectory represented by the trajectoryinformation is a predetermined given state, the object movementinformation acquisition part acquires the object movement informationadditionally including trajectory state information representing thegiven state; and

the video data retrieval part retrieves video data of a moving object,the video data meeting the retrieval condition including the trajectorystate information.

(Supplementary Note 12)

The video processing device according to any of Supplementary Notes 8 to11, further comprising a retrieval condition input part configured toinput the retrieval condition by drawing a line on a background showingthe segment regions.

(Supplementary Note 13)

The video processing device according to Supplementary Note 11, furthercomprising a retrieval condition input part configured to input thetrajectory state information by performing a predetermined givenoperation when drawing a line on a background showing the segmentregions.

(Supplementary Note 14)

The video processing device according to any of Supplementary Notes 8 to13, wherein the object movement information acquisition part isconfigured to acquire the video data from one or a plurality of externaldevices.

(Supplementary Note 15)

A video processing method comprising:

acquiring segment region information and sequence information as aretrieval condition and retrieving video data of a moving object, thesegment region information being of a plurality of segment regionsobtained by dividing a monitoring target area, the sequence informationbeing of a sequence of the segment regions where a moving object haspassed, the video data meeting the acquired retrieval condition; and

outputting the retrieved video data.

(Supplementary Note 16)

The video processing method according to Supplementary Note 15, furthercomprising:

detecting a moving object from video data and acquiring movement segmentregion information as object movement information, the video data beingobtained by separating a monitoring target area into a predeterminedplurality of segment regions and shooting the monitoring target area,the moving object moving in the plurality of segment regions, themovement segment region information representing segment regions wherethe detected moving object has moved;

storing the acquired object movement information in association with thevideo data corresponding to the object movement information; and

retrieving video data corresponding to the object movement information.

(Supplementary Note 17)

The video processing method according to Supplementary Note 16, furthercomprising:

acquiring a trajectory as trajectory information from the video data,the trajectory being of movement of the moving object in the pluralityof segment regions; and

acquiring the object movement information by associating the trajectorywith the predetermined plurality of segment regions, the trajectorybeing represented by the acquired trajectory information.

(Supplementary Note 18)

A computer program comprising instructions for causing a videoprocessing device to function as:

a video data retrieval part configured to acquire segment regioninformation and sequence information as a retrieval condition andretrieve video data of a moving object, the segment region informationbeing of a plurality of segment regions obtained by dividing amonitoring target area, the sequence information being of sequence ofthe segment regions where a moving object has passed, the video datameeting the acquired retrieval condition; and

a video data output part configured to output the video data acquired bythe video data retrieval part.

(Supplementary Note 19)

The computer program according to Supplementary Note 18, furthercomprising instructions for causing the video processing device tofunction as a video data storage part configured to store video data,

wherein the video data retrieval part acquires video data stored by thevideo data storage part and retrieves video data of the moving object,the video data meeting the retrieval condition.

(Supplementary Note 20)

The computer program according to Supplementary Note 19, furthercomprising instructions for causing the video processing device tofunction as:

an object movement information acquisition part configured to detects amoving object from video data and acquire movement segment regioninformation as object movement information, the video data beingobtained by separating a monitoring target area into a predeterminedplurality of segment regions and by shooting the monitoring target area,the moving object moving in the plurality of segment regions, themovement segment region information representing segment regions wherethe detected moving object has moved,

wherein the video data storage part stores the object movementinformation in association with video data corresponding to the objectmovement information, the object movement information being acquired bythe object movement information acquisition part.

The program disclosed in the exemplary embodiments and supplementarynote is stored in a storage device or recorded on a computer-readablerecording medium. For example, the recording medium is a portable mediumsuch as a flexible disk, an optical disk, a magneto-optical disk, or asemiconductor memory.

Although the present invention has been described above referring to theexemplary embodiments, the present invention is not limited to theexemplary embodiments described above. The configurations and details ofthe present invention can be modified and changed in various mannersthat can be understood by one skilled in the art within the scope of thepresent invention.

This application is based upon and claims the benefit of priority fromJapanese patent application No. 2014-026467, filed on Feb. 14, 2014, thedisclosure of which is incorporated herein in its entirety by reference.

DESCRIPTION OF REFERENCE NUMERALS

-   1 video processing device-   11 object movement information acquisition part-   12 video data and metadata DB-   13 retrieval condition input part-   14 metadata check part-   2 video processing device-   3 trajectory information acquisition part-   31 video data reception part-   32 trajectory information acquisition part-   4 object movement information acquisition part-   41 segment region and path defining part-   42 trajectory information and segment region associating part-   5 metadata accumulation part-   6 retrieval condition input part-   61 query input part-   62 gesture recognition part-   7 metadata check part-   8 video data accumulation part-   9 video processing system-   91 video data acquiring means-   92 object movement information acquiring means-   93 object movement information and video data storing means-   94 retrieval condition inputting means-   95 video data retrieving means-   10 video processing device-   101 object movement information acquiring means-   102 object movement information and video data storing means-   103 retrieval condition inputting means-   104 video data retrieval part

What is claimed is:
 1. A video processing system comprising at least oneprocessor configured to: detect a moving object from video data, thevideo data representing a target area comprising a plurality ofpredetermined segments; acquire object movement information representinga sequence or time that the detected moving object has passed theplurality of predetermined segments; receive a retrieval conditionrepresenting a sequence of the plurality of predetermined segments;access a database based on the retrieval condition, wherein the databasecomprises stored object movement information and stored video data, thestored object movement information indicates a plurality of previousobject movements, and each of the plurality of previous object movementsis associated with a corresponding portion of the stored video data;retrieve the object movement information and associated stored videodata that correspond to the retrieval condition from the database bycomparing the retrieval condition and a sequence that the moving objectpassed through the plurality of predetermined segments represented bythe plurality of previous object movements stored in the database; andoutput retrieved video data corresponding to the retrieval condition. 2.The video processing system according to claim 1, wherein the at leastone processor is further configured to acquire a trajectory astrajectory information from the video data representing the target area,the trajectory representing movement of the moving object in theplurality of predetermined segments, and wherein the at least oneprocessor is further configured to acquire the object movementinformation by associating the trajectory with the plurality ofpredetermined segments, the trajectory being represented by the acquiredtrajectory information.
 3. The video processing system according toclaim 2, wherein the at least one processor is further configured to:acquire, in a case where a state of the trajectory represented by thetrajectory information is a predetermined given state, the objectmovement information additionally including trajectory state informationrepresenting the given state; and receive the retrieval conditionadditionally including the trajectory state information.
 4. The videoprocessing system according to claim 3, wherein the at least oneprocessor is further configured to receive the trajectory stateinformation based on an input of a predetermined given operation that isperformed when drawing a line on a background showing the plurality ofpredetermined segments.
 5. The video processing system according toclaim 1, wherein the at least one processor is further configured toreceive the retrieval condition based on an input of a drawing of a lineon a background showing the plurality of predetermined segments.
 6. Thevideo processing system according to claim 1, wherein the at least oneprocessor is further configured to acquire the video data of the targetarea.
 7. A video processing device comprising: at least one processorconfigured to implement: a video data retrieval part configured to,based on video data representing a target area comprising a plurality ofpredetermined segments, receive a retrieval condition representing asequence of the plurality of predetermined segments, access a databasebased on the retrieval condition, and retrieve video data of a movingobject corresponding to the retrieval condition by comparing theretrieval condition and a sequence that the moving object passed throughthe plurality of predetermined segments represented by a plurality ofprevious object movements stored in the database, wherein the databasecomprises stored object movement information and stored video data, thestored object movement information indicates the plurality of previousobject movements, and each of the plurality of previous object movementsis associated with a corresponding portion of the stored video data; anda video data output part configured to output the retrieved video datacorresponding to the retrieval condition.
 8. The video processing deviceaccording to claim 7, wherein the at least one processor is furtherconfigured to implement a video data storage part configured to storethe video data representing the target area, wherein the video dataretrieval part is further configured to acquire the video datarepresenting the target area stored in the video data storage part andretrieve the video data of the moving object based on the video data ofthe moving object meeting the retrieval condition.
 9. The videoprocessing device according to claim 8, wherein the at least oneprocessor is further configured to implement an object movementinformation acquisition part configured to detect the moving object fromthe video data representing the target area and acquire the objectmovement information, the moving object moving in the plurality ofpredetermined segments, the object movement information representing asequence in which or time at which the detected moving object has passedthe plurality of predetermined segments, and wherein the video datastorage part is configured to store the object movement information inassociation with the video data representing the target area and thatcorresponds to the object movement information, the object movementinformation being acquired by the object movement informationacquisition part.
 10. The video processing device according to claim 9,wherein the at least one processor is further configured to implement atrajectory information acquisition part configured to acquire atrajectory as trajectory information from the video data representingthe target area, the trajectory representing movement of the movingobject in the plurality of predetermined segments, and wherein theobject movement information acquisition part is configured to acquirethe object movement information by associating the trajectory with theplurality of predetermined segments, the trajectory being represented bythe trajectory information acquired by the trajectory informationacquisition part.
 11. The video processing device according to claim 10,wherein: the object movement information acquisition part is furtherconfigured to, in a case where a state of the trajectory represented bythe trajectory information is a predetermined given state, acquire theobject movement information additionally including trajectory stateinformation representing the predetermined given state; and the videodata retrieval part is further configured to retrieve the video data ofthe moving object based on the video data of the moving object meetingthe retrieval condition including the trajectory state information. 12.The video processing device according to claim 11, wherein the at leastone processor is further configured to implement a retrieval conditioninput part configured to input the trajectory state information based ona predetermined given operation being performed when drawing a line on abackground showing a border of each of the plurality of predeterminedsegments.
 13. The video processing device according to claim 8, whereinthe at least one processor is further configured to implement aretrieval condition input part configured to input the retrievalcondition based on a drawing of a line on a background showing a borderof each of the plurality of predetermined segments.
 14. The videoprocessing device according to claim 8, wherein the object movementinformation acquisition part is configured to acquire the video datarepresenting the target area from one or more external devices.
 15. Avideo processing method executed by a video processing device, the videoprocessing method comprising: receiving, based on video datarepresenting a target area comprising a plurality of predeterminedsegments, a retrieval condition representing a sequence of the pluralityof predetermined segments; accessing a database based on the retrievalcondition, wherein the database comprises stored object movementinformation and stored video data, the stored object movementinformation indicates a plurality of previous object movements, and eachof the plurality of previous object movements is associated with acorresponding portion of the stored video data; retrieving video data ofa moving object corresponding to the retrieval condition by comparingthe retrieval condition and a sequence that the moving object passedthrough the plurality of predetermined segments represented by theplurality of previous object movements stored in the database; andoutputting the retrieved video data corresponding to the retrievalcondition.
 16. The video processing method executed by the videoprocessing device according to claim 15, the video processing methodfurther comprising: detecting the moving object from the video datarepresenting the target area; acquiring object movement informationrepresenting a sequence in which or time at which the detected movingobject has passed the plurality of segment regions; storing the acquiredobject movement information in association with the video datarepresenting the target area and corresponding to the object movementinformation; and retrieving the video data corresponding to the objectmovement information.
 17. The video processing method executed by thevideo processing device according to claim 16, the video processingmethod further comprising: acquiring a trajectory as trajectoryinformation from the video data representing the target area, thetrajectory representing movement of the moving object in the pluralityof predetermined segments; and acquiring the object movement informationby associating the trajectory with the plurality of predeterminedsegments, the trajectory being represented by the acquired trajectoryinformation.